DE942891C - Stretched ceilings and original carriers for their production - Google Patents

Description

Stretched ceilings and original beams that are used to produce them The invention forms a further development of that dealt with in the main patent Ceilings, in particular the arrangement and design of the so-called original beams, which are clamped together from individual stones.

It has already been suggested that original beams be made from individual stones of U-shaped cross-section between beam heads or from ceiling stones is more common Clamp the shape between headstones.

With the currently known U-stones, the connection between the original carrier and the reinforcement layer consists of a dovetail-shaped toothing, ie the webs of the U-profile are wider at the top than at the bottom. These stones as well as the ceiling stones must be made upright. This means that the stone length cannot be greater than about 25 cm. In the way these stones are manufactured, it is also difficult to manufacture the end faces of the individual stones so precisely that, immediately after the stones have been clamped together, the original carrier is sufficiently stable for further work (application of the reinforcement layer).

The invention consists in the fact that such stones are used lying down and in a much greater length and with the base area exactly vertical end faces can be produced. These are ceiling stones in which the upper wall is omitted, which is the shape of a U with side flanges to have. Allow the exact end faces that are exactly perpendicular to the base area with very thin joints too work, the number of joints decreases as a result of larger stone length by half, therefore not a large part of the clamping force is possible lost by pressing the joints together; the compression of the stones is thus more effective.

In the main patent, the tension wires are in the previous U-stone Anchored within the U-profile in concrete beam heads. Will against it In a further embodiment of the invention, the tension wires outside the U-profile arranged, ready-made cobblestones can be used at the ends to which the Tension wires anchored, tightened and pre-tensioned immediately after the stones have been put together can be.

In a further embodiment of the invention, the cobblestones are on the outside End inclined upwards towards the inside of the carrier, whereby through the upper, more inclined Bevel part makes it easier to pull over the knotted wire and by tapping the wire gently down the lower, steeper bevel portion the tightening takes place.

Within the U-shape - are in a further embodiment of the invention the side bars of the U-profile connected with cross bars, so that a good lateral stiffness also arises when the inside of the U-profile is not or not yet with concrete is filled out.

The one made from such original beams laid side by side The ceiling can be designed in a wide variety of ways, namely as a ceiling with cavities or as a full concrete ceiling. In the case of ceilings with cavities, these cavities can be completely or partially filled with insulating material and with the wooden floor or a top concrete slab to be completed. So you have the advantage that with a and the same stone insulating ceilings for residential construction and also heavily loaded ceilings can be made for industrial buildings.

Exemplary embodiments of the invention are shown in the drawing. It shows Fig. I an isometric partial view of the original carrier according to the invention, Fig. 2 shows a single block of the beam, Fig. 3 shows the pre-bent reinforcing wire, Fig. 4 the closure with the help of which this wire is knotted together, FIGS. 5 to 8 different types of ceilings: i denotes the original beam. It is composed of the individual stones 27 and the head stones 52, which are are at the ends of the beam. The original beams i are produced by that the head stones 52 and the normal stones 27 by stretching the on the head stones 52 anchored wire 7 are pressed together.

The side webs 53 of the U-shaped stones 27 are narrower at the upper edge than at the foot, so that it is possible to produce these stones lying down. At this In the case of precise production matrices, the end faces of the stones are the type of production exactly perpendicular to the base, and can also be used for horizontal stone production the stone length can be kept much longer than with those stones that must be made upright.

The stones 27 receive side flanges 31. The two side webs 53 of the stone 27 are connected to one another by the stiffening webs 54. At Toothed lugs 55 are attached to the outer sides of the webs 53, which also, like shown in Fig. 2, can be arranged so that a toothed outer surface the side webs 53 arise. Bores 56 of the side webs 53 are for pulling in a possible transverse reinforcement of the finished ceiling.

The head stones 52 are also U-shaped and have side flanges 3i, stiffening webs 54, toothed lugs 55 and provided with bores 56. At the outer end of the head stone 52, its side webs 53 are up against the The inside of the girder is inclined in such a way that an upper, more inclined contact surface 57 and a lower, steeper contact surface 58 arises.

The tension wire 7, with which the stones are clamped together, is pre-bent in the length determined by the number of stones, as shown in FIG. 3 is. Before the introduction of the wire 7, its ends 59 are through the pin 6o and the locking ring 61 knotted (Fig. 4). That wire knotted together 7 is placed over the cobblestones, which is caused by the upper bevel 57 of the cobblestone ends is facilitated. The wire comes into position 7 ″ on the dotted line Kink point between the two contact surfaces 57 and 58. By pressing down or Knock down by only a small amount along the steeper run-up surface 58 the wire brought into the tightened position 7 ', which is shown in dashed lines. That Stretching the wire 7 is done by changing direction downwards by over the bore 56 of the side webs 53 of the head stone 52 of the wire from the position 7 'through Lever pressure is lowered to the lower position and through a through hole 56 inserted cross bar 62 is held in the lowered position.

When the individual stones 27 and the head stones 52 are put together, the end faces receive only a very thin layer of cement paste. By knocking the stones together, any superfluous pulp is squeezed out, so that the colliding stones are not mortared in their joint 28, but rather are only glued, so to speak. By a slight setback of the end faces of the side flanges 31 compared to the main end face, a stronger joint 29 can arise when the side flanges 31 collide, which is necessary if the side flanges 3 1 of the stones 27 are to be excluded from the compression. In a similar way, the bottom 33 between the side webs 53 can also be excluded from the pressing.

Due to the exactly perpendicular position of the end faces to the base area the stones 27 and 52 this thin adhesive joint is possible, and it arises as a result When the joints are pressed together, there is only a very slight loss of tension. The through the bigger Reduced number of joints due to the length of the stones the already low voltage loss even further. Practice has shown that the well-known standing stones in all types of production (shaking or stamping) when assembling a certain. Do not do without a layer of mortar can. The loss of tension was therefore also in the stones produced in a standing position relatively large due to the larger number of joints.

This original beam i, which is clamped together from individual stones, is instant load-bearing and is laid under construction and supported once or twice depending on the length.

In Fig. 5 to 8 are different embodiments of the with the invention Original beam made ceiling drawn. The ceiling is created by a reinforcing layer 2 made of concrete, which is interlocked with the original carrier i will.

According to FIG. 5, this reinforcement layer 2 consists of the concrete introduced into the space above the flanges 3 1 by two carriers, which can also extend beyond the upper edge of the stone. The connection of the reinforcement layer 2 to the carrier i is effected not only by the adhesion but also by the toothed lugs 55. In the space 63, the inside of the U-profile; no reinforcement concrete is placed here. The cavity 63 is closed by the floor 64, which rests on the wooden supports 65. These pieces of wood 65 are supported on stiffening webs 54, and an insulating strip 66 can be placed between stiffening web 54 and bearing wood 65 to dampen the impact sound. For further sound and heat insulation, the cavity 63 can be completely or partially filled with insulating material.

According to Fig. 6, the reinforcement layer 2 consists of the ribbed concrete over the flanges of two beams i and from the one extending over the entire ceiling Concrete that is paneled against space 63 by panels 67. One thus obtains A hollow body ceiling, which compared to the usual hollow body ceilings in terms of insulation can still win that before the introduction of the plates 67 of the space 63 partially .with an insulating material, e.g. B. fly ash is filled. It is well known that they work in many ways the cavities of such hollow ceilings as acoustic drums. On the other hand, you can with the usual Do not do anything hollow ceilings, while in the hollow ceiling according to FIG. 6 this sound effect is prevented by filling in the insulation material.

In the case of the ceiling according to Fig. 7, both the rooms are above the flanges 31 as well as the rooms 23 are filled with reinforcing concrete, which also extends over the upper edge of the stone can extend. This way you get an outspoken Reinforced concrete ceiling for the heaviest loads.

In Fig. 8, a hollow ceiling is shown in longitudinal section in which the reinforcement layer 2 made of the concrete over the flanges 31 of two adjacent ones Carrier i, the pressure plates 68 over the stones and the pressure transfer strip 29 consists of concrete between the plates 68. The fibreboard 69, which is on the adjacent stiffening webs 54 of two adjoining stones 27 or 52 rest, serve as supports for the pressure plates 68 and at the same time as impact sound absorption.

With one and the same stone. for the production of the original carrier So different types of ceilings can be used, which is a very large one Means manufacturing advantage.

Claims (4)

PATENT CLAIMS: i. Stretched ceilings with composed of individual stones Original carriers. by changing the direction of tension wires on their undersides obtained an internal compressive stress and that by applying a reinforcing layer are combined to form the overall ceiling, according to patent 852 40, characterized in that the ceiling stones (27) forming the original support, open at the top, U-shaped or channel-shaped formed and with lateral lower flanges (3 i) and with exactly: perpendicular to the base area standing end faces are provided, while the tension wires (7) arranged outside the U-shaped or channel-shaped ceiling stones (27) and on head stones (52) are anchored, and that either the spaces (63) inside the U-shaped or channel-shaped Leave ceiling stones (27) as cavities or all spaces between the webs (53) of the stones (27) are filled with concrete. . 2. Original carrier for tensioned ceilings according to claim i, characterized in that the cobblestones (52) of the original support (i) at the outer front end for slipping over, tensioning and anchoring the tied together tension wire (7) with inclined and stepped Contact surfaces (57, 58) are provided. 3. original carrier according to claim 2, characterized characterized in that the looping around the original carrier for the purpose of issuing the prestress Wire (7) is provided with loop-like hooks at its ends (59), which when tightened and stretching the clamping forces transmitted to a pin (6o) and through a Circlip (6i) against bending and thus against loosening of the knot are secured. 4. original carrier according to claim 2 or 3, characterized in that the two side webs (53) of the ceiling stones (27) are connected to one another by stiffening transverse webs (54). Cited publications: German patent specifications 803 728, 8o5 793, 824024.